A simple strategy for dynamic substructuring: II. Experimental evaluation

Aikaterini Stefanaki; M. V. Sivaselvan; Scot Weinreber; Mark Pitman

doi:10.1002/eqe.3041

A simple strategy for dynamic substructuring: II. Experimental evaluation

Aikaterini Stefanaki
, M. V. Sivaselvan
, Scot Weinreber
, Mark Pitman

Department of Civil, Structural & Environmental Engineering

University at Buffalo

SUNY Buffalo

Research output: Contribution to journal › Article › peer-review

21 Scopus citations

Abstract

This paper is on an extensive experimental evaluation program to explore the robustness of a new strategy dynamic substructuring. This strategy, in contrast to conventional approaches, decouples the substructuring controller from the physical subsystem, and consequently results in a simple, yet robust, implementation. The concept is presented in detail in a companion paper. A configuration consisting of a shake table and an active mass driver is used in the experimental program, and various factors such as dynamics of virtual subsystems used, modeling of the actuator, choice of control gain settings, and nonlinear effects in the actuator are investigated, leading to the conclusion that the proposed strategy results in robust performance.

Original language	English
Pages (from-to)	1823-1843
Number of pages	21
Journal	Earthquake Engineering and Structural Dynamics
Volume	47
Issue number	9
DOIs	https://doi.org/10.1002/eqe.3041
State	Published - Jul 25 2018

Keywords

active mass driver
dynamic substructuring
hybrid simulation
hydraulic control parameters
saturation
shake table

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10.1002/eqe.3041

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abstract = "This paper is on an extensive experimental evaluation program to explore the robustness of a new strategy dynamic substructuring. This strategy, in contrast to conventional approaches, decouples the substructuring controller from the physical subsystem, and consequently results in a simple, yet robust, implementation. The concept is presented in detail in a companion paper. A configuration consisting of a shake table and an active mass driver is used in the experimental program, and various factors such as dynamics of virtual subsystems used, modeling of the actuator, choice of control gain settings, and nonlinear effects in the actuator are investigated, leading to the conclusion that the proposed strategy results in robust performance.",

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AU - Weinreber, Scot

AU - Pitman, Mark

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AB - This paper is on an extensive experimental evaluation program to explore the robustness of a new strategy dynamic substructuring. This strategy, in contrast to conventional approaches, decouples the substructuring controller from the physical subsystem, and consequently results in a simple, yet robust, implementation. The concept is presented in detail in a companion paper. A configuration consisting of a shake table and an active mass driver is used in the experimental program, and various factors such as dynamics of virtual subsystems used, modeling of the actuator, choice of control gain settings, and nonlinear effects in the actuator are investigated, leading to the conclusion that the proposed strategy results in robust performance.

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KW - hydraulic control parameters

KW - saturation

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JF - Earthquake Engineering and Structural Dynamics

IS - 9

ER -

A simple strategy for dynamic substructuring: II. Experimental evaluation

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Keywords

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